KR101534288B1 - Packing member for sealing pipe - Google Patents

Abstract

In particular, the present invention relates to a packing member inserted into a housing and extruded to an outer surface of a pipe, the packing member comprising: an inner peripheral portion extruded into the pipe; An outer peripheral portion 262 inserted into the housing and connected at one side to the inner peripheral portion 261 to form a fluid receiving portion 265 between the outer peripheral portion 262 and the outer peripheral portion 262; And the fluid receiving part (265) for receiving the fluid moving in the pipe, wherein the inner peripheral part (261) is brought into close contact with the outer surface of the pipe by the pressure of the received fluid, .
According to the present invention, since the packing member has the support portion, even if the packing member is exposed to a high-pressure fluid environment at the time of connection with the pipe or after installation, the shape of the packing can be maintained to provide a highly efficient watertight structure.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a piping connection packing member, and more particularly, to a piping watertight packing member that provides an improved watertight structure when connected to piping

In recent years, there has been a growing interest in the water quality of tap water, and the use of water pipes for stainless steel pipes, which are known to be the most suitable for water quality, has been attracting attention due to the importance of water quality problems.

Water pipes embedded in the basement and supplying tap water must have corrosion resistance to protect the inside water quality, water tightness of connection part, prevention of separation by water pressure and convenience of construction, and structural stability in response to external environment change are required . Stainless steel pipes are known to have material characteristics that best meet the requirements of such water pipes. In the case of such a stainless steel pipe having a small diameter of 13 A (0.8 T) to 50 A (1.2 T), a rubber ring is inserted into a socket having an enlarged pipe end, Can be used. Above 80A, the pipe thickness is 2.0T or more, and since it is impossible to work in the field by pressing method, there is a problem that the pipe must be connected through welding work. At this time, it is very difficult to weld a pipe having a diameter of 80 A or more to a work site, requiring a skilled welding technician, and the work process is delayed.

Flanges may be used to connect these water pipes. The flange may be adapted to receive and fix the ends of the two water pipes to be connected. The flanges are fixed to form a continuous flow path between the two water pipes so that the fluid can flow continuously. At this time, the flange should form a watertight structure to seal the connection with the water pipe.

In order to form a solid watertight structure, the packing and the water pipe must be strongly adhered to each other, and there should be no gap between the packing and the water pipe.

In addition, during the insertion of the water pipe into the packing, the packing may be dried by friction with the water pipe. In this case, the packing may not maintain its normal shape and may be folded or turned over on the outer peripheral surface of the water pipe.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a packing member capable of maintaining a shape by minimizing a drying phenomenon due to friction with a pipe during construction.

According to an aspect of the present invention, there is provided a packing member for a pipe watertight seal, comprising: an inner peripheral portion extruded into the pipe; An outer peripheral portion 262 inserted into the housing and connected at one side to the inner peripheral portion 261 to form a fluid receiving portion 265 between the outer peripheral portion 262 and the outer peripheral portion 262; And the fluid receiving part (265) for receiving the fluid moving in the pipe, wherein the inner peripheral part (261) is brought into close contact with the outer surface of the pipe by the pressure of the received fluid, Is formed.

In this case, the outer circumferential portion 262 is formed with a first flow path groove 266b, a second flow path groove 266a is formed in the inner circumferential portion 261, and the pipe is inserted into the inner circumferential portion 261 The first flow path groove 266b and the second flow path groove 266a are in contact with each other to form a flow path communicating with the fluid receiving portion 265. [

In addition, the packing member for pipe watertight sealing, which is one embodiment of the present invention, includes the inner circumferential portion 261 forming a plurality of inner circumferential protrusions 261a for increasing frictional force with the outer surface of the pipe. The outer peripheral portion 262 forming a plurality of outer peripheral projections 262a for increasing frictional force with the inner surface of the housing 200; .

In addition, the packing member for pipe watertightness, which is one embodiment of the present invention, is provided on the other side where the fluid receiving portion 265 is opened, and the end portion 2631 forms a certain distance from the pipe while the pipe is inserted And a support portion 263.

Another embodiment of the present invention is a pipe watertight packing member comprising a central separating portion 267 which is located between the inner peripheral portion 261 and the outer peripheral portion 262 and separates the fluid receiving portion 265 into two spaces, And further comprising:

In the packing member for pipe watertight sealing according to another embodiment of the present invention, a first flow path groove 266b is formed in the outer circumferential portion 262, a second flow path groove 266a is formed in the inner circumference portion 261, A third flow path groove is formed in the central separating portion 267. When the pipe is inserted into the inner main portion 261, the first flow path groove 266b and the third flow path groove 266c are in contact with each other, And the second flow path groove (266a) and the third flow path groove (266c) abut each other to form a flow path communicating with the fluid receiving portion (265).

According to the present invention, since the packing member has the support portion, even if the packing member is exposed to a high-pressure fluid environment at the time of connection with the pipe or after installation, the shape of the packing can be maintained to provide a highly efficient watertight structure.

Further, according to the present invention, it is possible to install the packing while maintaining the shape of the packing without a separate tool, so that it is easy to install in the field, the construction speed is very fast, and the quality of construction is excellent.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing a top view of a packing member for pipe watertight sealing according to an embodiment of the present invention. FIG.
FIG. 2 is a perspective view illustrating a bottom surface of a packing member for a pipe watertight seal according to an embodiment of the present invention. FIG.
3 is a cross-sectional view of a packing member for a pipe watertight seal, which is an embodiment of the present invention.
4 is a sectional view of a packing member for watertightness of pipes according to another embodiment of the present invention.
FIGS. 5 and 6 are schematic cross-sectional views showing a state in which a packing member for pipe watertight sealing, which is an embodiment of the present invention, is inserted.
FIG. 7 is a cross-sectional view of a packing member for pipe watertight sealing according to an embodiment of the present invention taken along the central axis. FIG.
8 is a view showing an incision along a central axis of a pipe in a state where a packing member for pipe watertightness, which is an embodiment of the present invention, is combined with a pipe and a housing.
9 is a perspective view showing a top view of a packing member for pipe watertight sealing according to another embodiment of the present invention.
10 is a cross-sectional view showing a part of a packing member for pipe watertight sealing which is another embodiment of the present invention.
11 is a perspective view showing a top view of a packing member for pipe watertight sealing, which is another embodiment of the present invention.
FIG. 12 is a cross-sectional view showing an incision along the central axis of a packing member for pipe watertight sealing, which is another embodiment of the present invention. FIG.
FIG. 13 is a view showing an incision of a part of a packing member for a pipe water-tightness and a housing, which is one embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

FIG. 1 is a perspective view showing a top surface of a packing member for pipe watertight sealing according to an embodiment of the present invention, FIG. 2 is a perspective view showing a bottom surface of a packing member for pipe watertight sealing, FIG. 4 is a cross-sectional view of a packing member for pipe watertight sealing according to another embodiment of the present invention, and FIGS. 5 and 6 are sectional views of a packing member for pipe watertight sealing, which is one embodiment of the present invention. FIG. 7 is a cross-sectional view showing a state in which the packing member for pipe watertight sealing, which is an embodiment of the present invention, is cut along the central axis, FIG. 8 is a cross- 9 is a view showing a state in which the member is cut along the central axis of the pipe in a state of being joined to the pipe and the housing, 10 is a cross-sectional view showing a part of a packing member for pipe watertight sealing, which is another embodiment of the present invention, and FIG. 11 is a perspective view showing a packing member for pipe watertight sealing, which is another embodiment of the present invention, And FIG. 12 is a view showing an incision of a part of a packing member for a pipe water-tightness and a housing, which is an embodiment of the present invention.

Referring to FIG. 1, a packing member for a pipe watertight seal, which is an embodiment of the present invention, is a packing member inserted into a housing and extruded to an outer surface of a pipe, the packing member comprising: an inner peripheral portion extruded into the pipe; An outer peripheral portion 262 inserted into the housing and connected at one side to the inner peripheral portion 261 to form a fluid receiving portion 265 between the outer peripheral portion 262 and the outer peripheral portion 262; And the fluid receiving part (265) for receiving the fluid moving in the pipe, wherein the inner peripheral part (261) is brought into close contact with the outer surface of the pipe by the pressure of the received fluid, Is formed.

The packing 260 is a component forming a watertight structure of a housing (for example, a flange or the like) to be inserted into the inner surface. The packing 260 may have a fluid receiving portion 265 formed therein to partially receive the fluid between the pipes to be connected.

The pipe may include all of the pipe shapes forming a hollow hole for receiving and moving the fluid in the pipe in addition to the water pipe.

Referring to FIG. 1, the packing 260 is formed in a ring shape as a whole. The packing 260 includes an inner peripheral portion 261 forming an inner peripheral surface and an outer peripheral portion 262 forming an outer peripheral surface. The inner peripheral portion 261 and the outer peripheral portion 262 are formed in a ring shape and are connected to each other to form a fluid receiving portion 265 as a constant space between the inner peripheral portion 261 and the outer peripheral portion 262.

Referring to FIG. 5, when connecting the pipe 1 to the flange, which is one embodiment of the housing 200, the pipe 1 is inserted into the packing 260. In this case, the inner circumferential portion 261 is folded in the direction of the outer circumferential portion 262, and the inner circumferential portion 261 and the end portion of the outer circumferential portion 262 come into contact with each other. However, the fluid receiving portion 265 inside the packing 260 can be maintained as a constant space.

The fluid receiving portion 265 may be filled with a hygroscopic expansion portion of a hygroscopic material. The hygroscopic expanding portion expands in volume when absorbing the fluid, thereby expanding the inflow / outflow expanding portion as compared with the case where only the fluid is introduced into the fluid receiving portion 265, thereby further enhancing the watertight structure performance.

The flow grooves 266 are formed at the ends of the inner and outer peripheral portions 261 and 262, respectively. The flow path groove 266 is formed in a groove shape from the end of each of the inner peripheral portion 261 and the outer peripheral portion 262 toward the fluid receiving portion 265. [

At this time, the flow grooves 266 formed in the inner peripheral portion 261 and the outer peripheral portion 262 are preferably formed at opposite positions. The flow path groove 266 formed in the inner peripheral portion 261 and the flow path groove 266 formed in the outer peripheral portion 262 come into contact with each other to form one flow path when the end portions of the inner peripheral portion 261 and the outer peripheral portion 262 come into contact with each other . The flow channel grooves 266 may be formed in at least one pair corresponding to the inner circumferential portion 261 and the outer circumferential portion 262.

In addition, independent flow paths may be formed in each of the inner peripheral portion 261 and the outer peripheral portion 262.

The outer peripheral portion 262 of the packing member for pipe watertightness which is one embodiment of the present invention is formed with a first flow path groove 266b and a second flow path groove 266a formed in the inner peripheral portion 261, When the pipe is inserted into the inner circumferential portion 261, the first flow path groove 266b and the second flow path groove 266a contact each other to form a flow path communicating with the fluid receiving portion 265 do.

3, a fluid receiving portion 265 is formed between the inner peripheral portion 261 and the outer peripheral portion 262, and the fluid receiving portion 265 is formed from the end of each of the inner peripheral portion 261 and the outer peripheral portion 262, The first flow path groove 266b and the second flow path groove 266a are formed.

When the inner circumferential portion 261 and the outer circumferential portion 262 come into contact with each other, the first flow path groove 266b and the second flow path groove 266a form one flow path and fluid can flow into the fluid receiving portion 265 from the outside .

Meanwhile, in the embodiment of the present invention, the cross-section of the fluid receiving portion 265, which is a constant space between the inner peripheral portion 261 and the outer peripheral portion 262, may be bent at a certain angle as shown in FIG. 3 , But it is not limited thereto as long as the fluid can be received and accommodated. For example, the cross-section of the fluid receiving portion 265 may be formed to have a larger diameter on the side where the fluid is introduced and gradually become narrower toward the inside. As shown in FIG. 4, And may be formed so as to keep the diameter constant in a certain region, which is preferable in view of easy introduction of the fluid.

The packing member for a pipe watertight seal according to an embodiment of the present invention includes the inner circumferential portion 261 forming a plurality of inner circumferential protrusions 261a for increasing frictional force with the outer circumferential surface of the pipe; The outer peripheral portion 262 forming a plurality of outer peripheral projections 262a for increasing frictional force with the inner surface of the housing 200; .

The inner circumferential portion 261 of the present invention forms a plurality of inner circumferential protrusions 261a for increasing the frictional force between the pipe and the outer circumferential surface.

The inner circumferential projection 261a is formed obliquely in the extrapolating direction to facilitate extrapolation of the inner circumferential portion 261 when the inner circumferential portion 261 is extruded in the direction D1 along the outer surface of the pipe as shown in Fig. .

After the extrusion of the inner peripheral portion 261 is completed and the fluid is received in the fluid receiving portion 265, the inner peripheral portion 261 presses the outer surface of the pipe to prevent the pipe from escaping. That is, the sawtooth-shaped inner circumferential projection 261a as shown in Fig. 5 presses the outer surface of the pipe while being compressed until the end portion 2631 of the support portion 263 comes into contact with the outer surface of the pipe.

As a result, the packing member for a pipe watertight structure, which is an embodiment of the present invention, facilitates the insertion of the pipe while achieving the effect of preventing the separation of the packing 260 and the pipe at the time of pressing through the fluid after the completion of insertion .

In addition, the outer peripheral portion 262 of the present invention forms a plurality of outer peripheral projections 262a for increasing the frictional force with the inner surface of the housing 200.

The outer peripheral projection 262a may be formed as a protruding projection as shown in FIG. 5, or may be formed in a saw-tooth shape as shown in FIG.

The outer circumferential projection 262a is pressed while being pressed against the inner surface of the housing 200 by the pressure of the fluid which is inserted into the housing 200 and is received in the fluid receiving portion 265. The present invention can prevent the housing 200 from rotating along the outer peripheral portion 262 of the packing 260 by increasing the binding force between the housing 200 and the packing 260.

The packing member for pipe watertightness, which is an embodiment of the present invention, may further include a support portion 263 forming an opening toward the pipe to be inserted.

That is, the fluid receiving portion 265 of the pipe watertight packing member, which is one embodiment of the present invention, is provided on the other side where the fluid receiving portion 265 is opened, and the end portion 2631 is provided with a support portion (263).

2 and 3, the support portion 263 is protrudingly formed on the other side where the fluid accommodating portion 265, which is the bottom surface of the packing 260, is opened and the inner circumferential portion 261 is dried by the frictional force with the pipe , And prevents the inner peripheral portion 261 from being dried by contacting the outer peripheral surface of the pipe.

One embodiment of the support portion 263 according to the present invention includes a support portion 262 that protrudes from the bottom surface of the packing 260 along the central axis of the packing 260 and is shaped like a "" .

If there is no frictional force between the pipe 1 and the packing 260, the packing 260 can be installed while maintaining the normal shape as shown in FIG. However, the packing 260 and the pipe 1 must be in close contact with each other for a solid watertight structure, and the pipe 1 must be pressed by the packing 260. A very large frictional force is generated between the packing 260 and the pipe 1 so that when the pipe 1 is inserted into the packing 260, the packing 260 is folded or dried as shown in FIG. 6 There is a problem that can occur.

That is, when the pipe 1 is installed, the inner peripheral portion 261 receives a force in a direction in which the pipe 1 is inserted in a direction opposite to the direction D1 in which the packing 260 advances due to the friction force with the pipe 1. [ The outer peripheral portion 262 receives an external force to advance in the direction D1 while the inner peripheral portion 261 receives a force in the direction opposite to the direction D1 due to the frictional force with the pipe 1 so that the packing 260 rotates counterclockwise I will continue to receive the power to do so.

According to the installation state as described above, the packing 260 may be installed in a form in which the packing 260 is deformed without keeping its normal shape due to curling or a part of the folding. Such deformation of the shape may occur even when the pressure of the fluid flowing in the pipe increases after the pipe and the flange are connected.

Even when the pressure of the fluid inside the pipe increases after the inner peripheral portion 261 is extruded along the outer surface of the pipe 1 and further after the connection between the pipe and the flange, the end of the supporting portion 263 is connected to the pipe 1 So that the above-described problems can be solved.

That is, the interface between the support portion 263 and the inner peripheral portion 261 or between the support portion 263 and the outer peripheral portion 262 is preferably in a state of being firmly connected by a method such as double injection.

The end portion 2631 of the support portion 263 is brought into contact with the pipe 1 when the packing 260 is deformed when the pipe 260 is connected to the pipe 1 as described above. The packing 260 resists the force of curling in the counterclockwise direction while the end of the support portion 263 is in contact with the pipe 1. [ As a result, it is possible to obtain an effect of preventing the packing 260 from drying in the counterclockwise direction within the hardness limit of the support portion 263.

Further, in the present invention, the support portion 263 may be formed of a material different from that of the inner peripheral portion 261 and the outer peripheral portion 262. In particular, the support portion 263 is preferably made of a material harder than the inner peripheral portion 261 and the outer peripheral portion 262. Such a double material structure can be implemented by a method such as double injection.

That is, when the support portion 263 is formed of a material having a hardness higher than that of the inner peripheral portion 261 and the outer peripheral portion 262, the opposing force against the deformation of the support portion 263 becomes higher, So that it can be maintained.

7 and 8, a process of forming the water-tight structure with the pipe 260 when the fluid is received in the fluid-receiving portion 265 will be described.

When the fluid pressure rises in the pipe 1, the fluid flows outwardly in the direction D2 of the pipe 1 through the end of the pipe 1 and then flows between the outer peripheral surface of the pipe 1 and the inner peripheral surface of the flange 1 As the process progresses, the other packing 280, 270 as shown in Fig. 7, which are located adjacent to each other, sequentially passes through the packing 260.

Next, the fluid may flow into the fluid receiving portion 265 through the flow path formed by abutting the first flow path groove 266b and the second flow path groove 266a.

In the case where relatively large pressure is generated as in the case where the other packings 280 and 270 sequentially form the watertight structure and the pressure of the fluid instantaneously increases, the watertight structure can be maintained by the packing 260 have.

The shape of the packing 260 may be deformed even under conditions of high fluid pressure as described above. Also in this case, the shape of the packing 260 can be prevented from being deformed by the support portion 263.

Another embodiment of the present invention is a pipe watertight packing member comprising a central separating portion 267 which is located between the inner peripheral portion 261 and the outer peripheral portion 262 and separates the fluid receiving portion 265 into two spaces, And further comprising:

9 and 10, one side of the central separating portion 267 of the pipe watertight packing member, which is one embodiment of the present invention, is connected to one side of the inner portion 261 or the inner portion of the outer peripheral portion 262, The first fluid receiving portion 265a and the second fluid receiving portion 265b are separated into two spaces.

The central separating portion 267 is preferably formed in a ring shape because it is positioned between the inner peripheral portion 261 and the outer peripheral portion 262 and forms two spaces in the fluid receiving portion 265.

5, when the flange and the pipe 1 are connected, the inner circumferential portion 261 is folded in the direction of the outer circumferential portion 262 so that the end portions of the inner circumferential portion 261 and the outer circumferential portion 262 come into contact with each other, The separating portion 267 abuts the inner peripheral portion 261 or the outer peripheral portion 262 but the first fluid receiving portion 265a or the second fluid receiving portion 265b can maintain a predetermined space.

The first fluid receiving portion 265a and the second fluid receiving portion 265b may be filled with a hygroscopic expansion portion of hygroscopic material similarly to the above.

The outer peripheral portion 262 may be formed with a first flow path groove 266b or the inner peripheral portion 261 may have a second flow path groove 266a formed therein, When the pipe is inserted into the inner peripheral portion 261, the first flow path groove 266b and the third flow path groove 266c are in contact with each other, And the second flow path groove (266a) and the third flow path groove (266c) abut each other to form a flow path communicating with the fluid containing portion (265).

The flow path groove 266 formed in the central separating portion 267 is formed in a groove shape from the end toward the first fluid receiving portion 265a or the second fluid receiving portion 265b.

The flow path groove 266 formed in the central separator 267 is preferably formed at a position opposite to the flow path groove 266 formed at the end of each of the inner circumferential portion 261 or the outer circumferential portion 262.

This is because the flow path groove 266 formed in the central separating portion 267 and the flow path groove 266 formed in the inner peripheral portion 261 come into contact with each other when the ends of the inner separating portion 267 and the inner separating portion 267 come into contact with each other It is preferable to form a flow path of the gas.

The flow path groove 266 formed in the central separating portion 267 and the flow path groove 266 formed in the outer peripheral portion 262 come into contact with each other when the ends of the central separating portion 267 and the outer peripheral portion 262 come into contact with each other, .

These flow grooves 266 may be formed as at least one pair of the center separating portion 267 and the inner circumferential portion 261 or the end portions of the central separating portion 267 and the outer circumferential portion 262.

Hereinafter, this will be described in more detail with reference to Figs. 9 and 10. Fig.

A first fluid receiving portion 265a is formed between the central separating portion 267 and the inner circumferential portion 261 and a first fluid receiving portion 265b is formed from the end of the central separating portion 267 and the inner circumferential portion 261, The third flow path groove 266c and the first flow path groove 266b are formed toward the receiving portion 265a.

The third flow path groove 266c and the first flow path groove 266b form one flow path when the center separating portion 267 and the inner circumferential portion 261 come into contact with each other to flow fluid from the outside into the first fluid receiving portion 265a .

The second fluid receiving portion 265b is formed between the central separating portion 267 and the outer peripheral portion 262 and the second fluid receiving portion 265b is formed from the end of the central separating portion 267 and the outer peripheral portion 262, The third flow path groove 266c and the second flow path groove 266a are formed.

The third flow path groove 266c and the second flow path groove 266a form one flow path in the case where the center separating portion 267 and the outer peripheral portion 262 are in contact with each other so that fluid flows from the outside into the second fluid receiving portion 265b So that it can be introduced.

11, the central separating portion 267 of the pipe watertight packing member of another embodiment of the present invention is inserted into the fluid receiving portion 265 and is inserted into the first fluid receiving portion 265a and the second fluid receiving portion 265a, And separated into two spaces as shown in Fig. Here, the central separating portion 267 is separable from the fluid receiving portion 265.

The central separating section 267 is composed of an inserting section 267a and a separating section 267b.

The insertion portion 267a is inserted into the inner surface of the fluid accommodating portion 265 and fixed to the step 261b formed on the inner surface of the inner peripheral portion 261 and the step 262b formed on the outer peripheral portion 262. [

The separating portion 267b is fixedly connected to the inserting portion 267a and separates the fluid receiving portion 265 into two spaces such as the first fluid receiving portion 265a and the second fluid receiving portion 265b.

Hereinafter, with reference to FIG. 12, description will be made of a process in which the fluid is received in the first fluid receiving portion 265a and the second fluid receiving portion 265b, and the packing 260 forms a watertight structure with the pipe. 12, the first fluid receiving portion 265a and the second fluid receiving portion 265b are present along the central axis of the pipe watertight packing member, which is another embodiment, And the cross section is shown.

When the fluid pressure rises in the pipe 1, the fluid flows outwardly in the direction D2 of the pipe 1 through the end of the pipe 1 and then flows between the outer peripheral surface of the pipe 1 and the inner peripheral surface of the flange 1 As the process progresses, the other packing 280, 270 as shown in FIG. 6, which are located adjacent to each other, sequentially passes through the packing 260.

Next, the fluid is supplied to the first fluid receiving portion 265a through the one flow path formed when the third flow path groove 266c and the first flow path groove 266b come into contact with the center separating portion 267 and the inner peripheral portion 261 And the third flow path groove 266c and the second flow path groove 266a are connected to each other through one flow path formed when the center separating portion 267 and the outer peripheral portion 262 are in contact with each other, The fluid may be introduced into the fluid chamber 265b.

In the case where relatively large pressure is generated as in the case where the other packings 280 and 270 sequentially form the watertight structure and the pressure of the fluid instantaneously increases, the watertight structure can be maintained by the packing 260 have.

Hereinafter, an embodiment of the use of a packing member for pipe watertightness according to an embodiment of the present invention will be described.

The housing 200 may be formed into a hollow tubular shape as shown in FIG. On the inner circumferential surface of the housing 200, a packing accommodating portion 201 and an insertion restricting portion 205 are formed from above with reference to Fig.

The packing receiving portion 201 is formed as a constant space portion formed by protruding outwardly from the inner peripheral surface of the housing 200. The packing receiving portion 201 receives the packing 260 and fixes the packing 260 on the inner peripheral surface of the housing 200.

The insertion restricting portion 205 is a component for restricting the insertion depth of the pipe inserted into the inside of the packing accommodating portion 201. The insertion restricting portion 205 is formed so as to protrude inwardly around the inner circumferential surface of the housing 200. The insertion restricting portion 205 may have an extended portion 206 protruding upward along the central axis direction. The extension 206 functions to limit the movement of the inserted pipe.

In addition, a hook-shaped first fixing protrusion 220 may be formed on the upper end of the housing 200, which is an end of the pipe on which the pipe is inserted, so that the clamp can be fastened.

Hereinafter, as shown in FIG. 7, a section of the housing 200 where the pipe 1 is inserted and received is referred to as a first accommodating portion P1. The portion where the other pipe connected to the pipe 1 is received and fixed is referred to as a second receiving portion P2. At this time, the other pipe may be fixed to the welded portion 209 provided at the end of the second accommodating portion P2 by welding. The flange can use not only the above-described welding method but also a conventional pipe fastening method such as a screw fastening method.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. It will be apparent to those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention as defined by the appended claims and their equivalents.

The first packing 260 fluid receiving portion 265,
The flow path groove 266, the first flow path groove 266b,
The inner circumferential portion 261 of the second flow path groove 266a,
The outer circumferential portion 262, the support portion 263,
The end 2631 interface (2632)

Claims (7)

A packing member inserted into a housing and extruded to an outer surface of a pipe,
An inner peripheral portion (261) extruded into the pipe;
An outer peripheral portion 262 inserted into the housing and connected at one side to the inner peripheral portion 261 to form a fluid receiving portion 265 between the inner peripheral portion 261 and the inner peripheral portion 261;
The fluid receiving portion (265) for receiving fluid moving in the pipe; And
And a central separating part (267) located between the inner peripheral part (261) and the outer peripheral part (262) and separating the fluid receiving part (265) into two spaces,
The inner circumference 261 is in close contact with the outer surface of the pipe due to the pressure of the fluid received therein to form a watertight structure with the pipe,
The central separating unit 267,
An insertion portion 267a inserted into the inner surface of the fluid receiving portion 265; And
And a separating part (267b) fixedly connected to the inserting part (267a) and separating the fluid receiving part (265) into two spaces. The method according to claim 1,
The outer circumferential portion 262 is formed with a first flow path groove 266b, the inner circumferential portion 261 is formed with a second flow path groove 266a,
When the pipe is inserted into the inner circumferential portion 261, the first flow path groove 266b and the second flow path groove 266a contact each other to form a flow path communicating with the fluid receiving portion 265 A packing member for watertightness of the pipe. The method according to claim 1,
An inner circumferential portion (261) forming a plurality of inner circumferential projections (261a) for increasing the frictional force between the pipe and the outer circumferential surface; or
The outer peripheral portion 262 forming a plurality of outer peripheral projections 262a for increasing frictional force with the inner surface of the housing 200; Wherein the packing member is made of a synthetic resin. The method according to claim 1,
And a support portion (263) provided at the other end where the fluid receiving portion (265) is opened, and the end portion (2631) forms a predetermined distance from the pipe while the pipe is inserted. Packing member. delete A packing member inserted into a housing and extruded to an outer surface of a pipe,
An inner peripheral portion (261) extruded into the pipe;
An outer peripheral portion 262 inserted into the housing and connected at one side to the inner peripheral portion 261 to form a fluid receiving portion 265 between the inner peripheral portion 261 and the inner peripheral portion 261;
The fluid receiving portion (265) for receiving fluid moving in the pipe; And
And a central separating part (267) located between the inner peripheral part (261) and the outer peripheral part (262) and separating the fluid receiving part (265) into two spaces,
A first flow path groove 266b is formed in the outer peripheral portion 262 or a second flow path groove 266a is formed in the inner peripheral portion 261,
A third flow path groove 266c is formed in the central separator 267,
When the pipe is inserted into the inner peripheral portion 261, the first flow path groove 266b and the third flow path groove 266c are in contact with each other or the second flow path groove 266a and the third flow path groove 266c ), And forms a flow path communicating with the fluid containing portion (265). delete

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